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than spherical. The ratio between the two values for the particle radius given by the two laws (rE/rs)is 1.43. This compares well with similar ratios already obtained in the cases of hemoglobin, serum albumin, serum globulin and phycocyan. This probably means that the departure of the particle from a spherical shape is about the same amount for all of these proteins. Summary 1. Casein prepared by the Hammarsten method has been examined a t PH G.8 in phosphate buffer solution by the centrifugal sedimentation velocity method and found to consist of a mixture of protein molecules of different weight. 2. Hammarsten casein was extracted with hot acidified 70% alcohol and the soluble protein precipitated out with dilute sodium hydroxide. This protein after washing was dissolved in phosphate buffer solution of PHG.8. Various concentrations were examined by both the sedimentation velocity and sedimentation equilibrium methods. 3. It was found that within the limits of experimental error the acidalcohol soluble protein was homogeneous with regard to molecular weight and that it therefore probably was a pure chemical individual. 4. The molecular weight was found to be 375,000 * 11,000. 5 . The molecule was not spherical and deviated from the spherical shape by about the same amount that has been found for several other proteins. UPSALA,SWEDEN GENEVA,NEW YORK [CONTRIBUTION FROM THE CHEMICAL LABORATORY OF THE UNIVERSITY OF WASHINGTON]
THE BENZILIC ACID REARRANGEMENT BY THEODORE W. EVANS AND WILLIAMM. DEHN R E C E I V ~JULY D 1, 1929
PUBLISHED JANUARY 8, 1930
It seems probable that the benzilic acid rearrangement is best formulated as follows CaH6
I CsHsC-C II II
0 0
CsH6
I f KOH +C6Hb-C-C-OK I1 I 0
OH
C6H6
I +CeHs-C-C-OK I
II
OH 0
The addition of one molecule of potash was postulated by Hoogewerff and van Dorp;* the migration of both C6Hb and H, by Michael;2 ex1 Hoogewerff and van Dorp, Rec. t r a ~ chim., . 9, 225 (1890). These authors assumed that Ph and OK migrate from one carbon atom to the other. 2 Michael, THISJOURNAL, 42, 814 (1920). Michael assumes the addition of one mole of potassium hydroxide, and this forms a system which “may now completely convert itself, by the transmigration of phenyl and hydrogen, into a salt of the relatively strong benzilic acid.”
Jan., 1930
T H E BENZILIC ACID REARRANGEMENT
253
perimental indication of CI4Hl0O2.KOHwas given by S c h e ~ i n g . ~It has been assumed that benzil adds to H20,4to 2 H ~ 0to , ~2KOH,6 or to KOH.’ Since it is possible to avoid waters and to limit the alkali to one molecule, it is possible to obtain definite proof not only that water is not necessary but that the intermediate additiveg compound is formed. All experiments directed toward increasing the yield of the acid have involved large excesses’O of alkali. Experiments of only theoretical interest have always involved either water alone, or alkali alcoholate alone, or alcoholic potash, or mixtures of these. In no case has only one molecule of benzil, one molecule of potash and an indifferent solvent such as ether, benzene, etc., been employed. We have treated equivalents of benzil, furil and diacetyl with potash in anhydrous ether and have found that only one molecule of potash is necessary for the transformation. A single lump of potassium hydroxide weighing 1.4 g., placed in absolute ether with 5.4 g. of benzil and shaken occasionally during four days, was replaced by 5.6 g. of a powdery, light yellow solid; the ether yielded 1 g. of unchanged benzil, melting a t 95”. The solid was analyzed. Anal. Calcd. for C~*HIOOZ,KOH: K, 14.68. Found: K, 15.04. a Scheuing, Ber., 56,252 (1923); 57, 1963 (1924). Schonberg, ibid., 58,235 (1925), criticizes Scheuing’s product as affording no proof of an intermediate compound, “da das Anlagerungsproduct weder analysiert noch sein molekular gewicht bestimmt worden ist.” 4 Nef, Ann., 298, 372 (1897). For a criticism of Nef’s interpretation see Michael, THISJOURNAL, 42, 812 (1920). 6 Lachman first assumed the addition of two molecules of water but later assumed only one molecule of water. Cf.THISJOURNAL, 44, 330 (1922), and 45, 1509, 1522, 1529 (1923); 46,779 (1924). His contention that a mobile hydroxyl group shifts, that water is necessary for the benzilic acid rearrangement and his use of the word “metakliny,” involving intramolecular oxidation and reduction, seem unjustified. 6 Tiffeneau, Rev. gen. sci., 585 (1907). Staudinger and Binkert, Helv. Chim. Acta, 5, 703 (1922). ‘I Schroeter, Ber., 42, 2336 (1909), also assumed initial addition of one mole of potassium hydroxide, but his theory of rearrangement, involving the intermediate formation of diphenylketene was disproved by Nicolet and Pelc, THISJOURNAL, 43, 935 (1921); see also Schonberg and Keller, Ber., 56,1638 (1923). * Lachman states unequivocally that water is necessary for the benzilic acid 46, 781 (1924). Others who have obrearrangement; see especially THISJOURNAL, served the effects of water are Jena, Ann., 155, 78 (1870); Klinger, Ber., 19, 1868 (1886). Scheuing used equivalents of alcoholic potash and bemil in ether solution and obtained a light yellow solid which he claimed was changed gradually a t 0 ” and rapidly a t 80 to potassium benzilate. lo From 3 to 8 equivalents of potassium hydroxide have been used. Liebig, Ann., 25, 27 (1838); Zinin, ibid., 31, 329 (1839); Limpricht and Schwandert, Ber, 2, 134 (1869); Jena, Ann., 155, 79 (1870); Fischer, Ber., 14, 326 (1881); Klinger, ibid., 22, 1212 (1889); H. v. Liebig, ibid., 41, 1644 (1908); Staudinger, Ann., 356, 71 (1907); “Organic Syntheses,” Vol. I, 1921, p. 29; Scheuing, Ber., 56, 255 (1923); Schonberg and Keller, ibid., 56, 1640 (1923). O
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Vol. 52
Some of this salt, treated with concentrated sulfuric acid, gave the characteristic red color which benzilic acid does." Upon acidifying 4.64 g. of this potassium benzilate, 3.71 g. (94%) of white needles of benzilic acid melting a t 150' were obtained. Since no benzaldehyde or benzoic acid was detected, the precipitate represented an 81% transformation to potassium benzilate. The transformation was effected in the absence of water and while the additive compound was in the solid state. In another experiment equivalents of materials were ground up in a mortar under dry ether, but owing to rise of temperature or unavoidable contact with atmospheric moisture and oxygen, the yield was poor and contained benzaldehyde and benzoic acid. From anhydrous ammonia, benzil and toluene was obtained a white solid, which proved to be benzilam,12 melting point a t 110'. With anhydrous ammonia, bemil and ether a white solid melting a t 158" was obtained. With potash, it yielded ammonia and a white solid, insoluble in water, and melting a t 203 '. It will be further investigated. When 5 g. of furil and 1 g. of sodium hydroxide in dry ether were shaken during twenty-four hours, 5.33 g. (88%)of a dark brown powdery mass was obtained. Anal. Calcd. for CloH~O~.NaOH: Na, 10.00. Found: Na, 10.27. Acidification of the salt and extraction with ether yielded white needles of furilic acid agreeing in all properties with Fischer's product.'3 With 10 g. of diacetyl and 6.5 g. of potassium hydroxide in dry ether, an immediate blackening of the potash resulted; the final sticky mass was brown-black, and though it contained acetaldehyde, resin, acetic acid and other products, it could not be made to yield dimethylglycolic acid.
Summary One molecule of potash transforms benzil to benzilic acid; water is not necessary for this reaction. An additive compound is first formed which undergoes molecular rearrangement while in the solid phase. SEATTLE, WASHINGTON 11 We have observed that 60% perchloric acid and 85% phosphoric acid also give red colorations with benzilic acid. l 2 Laurent, J . prakt. Chem., [ l ]35, 461 (1846). 13 Fischer, Ann., 211, 222 (1884).